Maximum intensity projections of confocal images used to quantify microcapillary-like structure directionality and containment (DOA and DOC). Values used and statistical analysis summary is included as well as a sample full image stack. Any further data including raw images available upon request.

Maximum intensity projections of confocal images used to quantify microcapillary-like structure directionality and containment (DOA and DOC). Values used and statistical analysis summary is included as well as a sample full image stack. Any further data including raw images available upon request.

Maximum intensity projections of confocal images used to quantify microcapillary-like structure directionality and containment (DOA and DOC). Values used and statistical analysis summary is included as well as a sample full image stack. Any further data including raw images available upon request.

Maximum intensity projections of confocal images used to quantify microcapillary-like structure directionality and containment (DOA and DOC). Values used and statistical analysis summary is included as well as a sample full image stack. Any further data including raw images available upon request.

Maximum intensity projections of confocal images used to quantify microcapillary-like structure directionality and containment (DOA and DOC). Values used and statistical analysis summary is included as well as a sample full image stack. Any further data including raw images available upon request.

Maximum intensity projections of confocal images used to quantify microcapillary-like structure directionality and containment (DOA and DOC). Values used and statistical analysis summary is included as well as a sample full image stack. Any further data including raw images available upon request.

This work was funded by the National Science Centre grants, NN 401 584238 (MZ) and 2012/07/N/ NZ3/01943 (JU-P), a programme grant from the UK Multiple Sclerosis Society (RJMF, CZ) and a core support grant from the Wellcome Trust and MRC to the Wellcome Trust – Medical Research Council Cambridge Stem Cell Institute (RJMF).

This work was funded by the National Science Centre grants, NN 401 584238 (MZ) and 2012/07/N/ NZ3/01943 (JU-P), a programme grant from the UK Multiple Sclerosis Society (RJMF, CZ) and a core support grant from the Wellcome Trust and MRC to the Wellcome Trust – Medical Research Council Cambridge Stem Cell Institute (RJMF).

This work was funded by the National Science Centre grants, NN 401 584238 (MZ) and 2012/07/N/ NZ3/01943 (JU-P), a programme grant from the UK Multiple Sclerosis Society (RJMF, CZ) and a core support grant from the Wellcome Trust and MRC to the Wellcome Trust – Medical Research Council Cambridge Stem Cell Institute (RJMF).